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Non-Photorealistic Rendering: Toon Shading

Non-Photorealistic Rendering: Toon Shading. David Luebke University of Virginia. Admin. Changes to remaining assignments. Non-Photorealistic Rendering. “Using a term like ‘nonlinear science’ is like referring to the bulk of zoology as ‘the study of nonelephant animals’”

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Non-Photorealistic Rendering: Toon Shading

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  1. Non-Photorealistic Rendering:Toon Shading David Luebke University of Virginia

  2. Admin • Changes to remaining assignments

  3. Non-Photorealistic Rendering “Using a term like ‘nonlinear science’ is like referring to the bulk of zoology as ‘the study of nonelephant animals’” • Photorealism: age-old goal of graphics • Non-photorealistic rendering • Broadly, techniques for rendering that don’t strive for realism, but style, expressiveness, abstraction, uncertainty, etc • A terrible, terrible term that we’re probably stuck with • Better terms: stylized rendering, artistic rendering, abstract rendering

  4. Stylized Rendering • NPR is most commonly used to refer to graphics techniques that emulate a particular artistic style or medium • Impressionistic painting • Pen-and-ink (cross hatching, outlining, etc) • Colored-pencil, copperplate engraving, you name it • Cartoon drawing

  5. Toon shading • Toon shading is the term that we use to refer to cartoon-like rendering effects • Tendencies in cartoon/comic style: • Simple, flat shading (cel shading) • Two-tone (light/shadow) or three-tone (light/shadow/highlight) • Edge highlighting • Boundary (border edge) • Crease (hard edge) • Material edge • Silhouette edge

  6. Toon Shading • Cel shading • Threshold the lighting equation • Ex: the Cg program we looked at • Diffuse below 0.5 ? dark color : light color • Specular above 0.5 ? hilight color : diffuse color • If no pixel shaders, can use N ● L to look up a 1-D texture containing the shaded colors • In general, can think of these procedures as remapping the traditional lighting equation elements (tone mapping)

  7. Silhouette Rendering • Boundary (border edge) • Not shared by two polygons • E.g. the edge of a sheet of paper • Solid models usually have no boundaries • Crease (hard edge) • Shared by two polygons at a dihedral angle greater than some threshold (often 60°) • Or a vertex with two normals/two colocated vertices • Ridge or valley edges

  8. Silhouette Rendering • Material edge • Triangles sharing edge have different materials/texture maps/etc • Or just an edge that the artist wants to emphasize • Silhouette edge • Triangles sharing edge face different directions (towards/away from viewer) • Lots of techniques to find at runtime!

  9. Finding/Rendering Silhouette Edges • Surface angle silhouetting • Again, like the Cg program we looked at • Calculate N●V, if below threshold  draw black • Problem: depends on surface curvature (see Fig 7.5)

  10. Procedural Geometry Silhouetting • Idea: render the geometry in such a way that the silhouettes “fall out” • Ex: • Draw frontfacing polygons • Draw backfacing polygons • But draw them in thick (2-pixel) wireframe • Or draw them in wireframe, z-biased forward a bit • Or “fatten” them • Or displace them along their normals (“halo” effect)

  11. Results Wireframe Translation Fattening 40 fps 50 fps 11.5 fps Original Venus model : 5672 triangles, 66 fps

  12. Image Processing Silhouetting • Idea: analyze the image after it’s rendered, and extract silhouettes (like edge detection) • Can help by rendering e.g. depth image, object-ID image, normal image • Perfect for fragment program!

  13. Silhouette Edge Detection • Idea: find silhouette edges geometrically and render them explicitly • Randomized Appel’s algorithm • Lots of interesting geometric approaches • Most work, but gives the most flexibility in how silhouettes are drawn

  14. Non-Photorealistic RenderingDrawing, Hatching, Painting David Luebke University of Virginia

  15. Recap: Edge Highlighting • Toon shading (and other NPR techniques based on drawing) requires some edges be drawn or highlighted: • Silhouette edges • Mesh boundaries (always on silhouette) • Creases (ridge and valley) • Material boundaries • Find first at run-time, precalculate the others (unless object is deformable)

  16. Recap: Silhouette Edges • Surface angle silhouetting • Calc N●V, if below threshold  draw black • Best as a per-pixel routine • The Cg program we looked at • Also can do with a spheremap, or use a mip-map with top-level textures dark • Pros: • Uses the texture hardware  fast • Can antialias the resulting lines • Cons: • Line width depends on curvature • Doesn’t work for some models (e.g., a cube)

  17. Recap: Silhouette Edges • Procedural Geometry Silhouetting • Idea: render the geometry in such a way that the silhouettes “fall out”, e.g.: • Draw frontfacing polygons • Draw backfacing polygons • But draw them in (possibly thick) wireframe • Or draw them z-biased forward a bit • Or “fatten” them • Or displace them along their normals (“halo” effect) • Flip normals • Amount of displacement varies w/ distance (why?) • Perfect task for vertex shader! • Pros: relatively robust, doesn’t need connectivity info • Cons: Wastes some fill & some polys, needs antialiasing

  18. Results Wireframe Translation Fattening 40 fps 50 fps 11.5 fps Original Venus model : 5672 triangles, 66 fps

  19. Recap: Silhouette Edges • Image Processing Silhouetting • Idea: analyze the image after it’s rendered, and extract silhouettes (i.e., edge detection) • Perfect for fragment program! • Can help by rendering e.g. depth image, object-ID image, normal image

  20. Recap: Silhouette Edges • Silhouette Edge Detection • Idea: find silhouette edges geometrically on the CPU and render them explicitly • Brute force: test every edge to see if its adjoining polygons face opposite directions in eye space • Can speed this up with randomized coherent search • Most work, but gives the most flexibility in how silhouettes are drawn • GPU variant: • Draw degenerate quadrilateral at each edge • Use vertex shader to “fatten” quad into a “fin” when edge is on silhouette • Fin thickness based on distance to eyepoint

  21. Highlighting Ridge Edges • Clever related technique by Raskar: • Add “fins” to every edge at dihedral angle • Size fins according to distance to viewer • Again, perfect for vertex shader • Similar but more complicated technique for highlighting valley edges

  22. Drawing Lines:Outlining Polygons • Surprisingly hard to draw polys as filled outlines • Problem: depth buffer values of edge & polys same • 2-pass technique: draw polys, then draw edges • Z-bias edges forward or polygons back (glPolygonOffset) • Works okay, but has occasional problems • 3-pass technique: • Render filled polygon • Disable depth buffer writes (leave depth test on) • Enable color buffer writes • Render polygon edges polygon • Normal depth & color buffering • Render filled polygon again • Enable depth buffer writes • Disable color buffer writes

  23. Drawing Lines:Hidden-Line Rendering • Hidden-line vs. obscured line vs halos • Hidden-line • Draw polygons to depth buffer (not color buffer) • Draw edges using previous technique • Obscured (light, dotted, dashed) line • Draw all edges in obscured style • Draw polygons to depth buffer (not color buffer) • Draw edges using previous technique • Haloed line • Draw all edges as thick background-color lines • Draw edges using biasing, foreground-color

  24. Other Styles • Impressionistic or “painterly” rendering: • Sprinkle particles on object surface • Draw particles as brushstrokes • Can render images to encode normals, surface curvature, depth, color/tone info

  25. Painterly Rendering • More info if time permits…

  26. Other Styles • Hatching: • Store different cross-hatch patterns representing different tones as textures • Clever ways to use texture hardware to blend between tones at run-time • More info if time permits…

  27. Other Styles • “Graftals” are a general term used for strokes, decals, little bits of geometry • Dynamic placement of graftals to achieve certain effects/styles:

  28. Other Styles • Technical Illustration

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